Method and device for displaying and browsing a multi-faceted data set

ABSTRACT

This invention aims to provide a method and apparatus for displaying and/or browsing a multi-faceted data set containing hierarchical subject labels. In the present invention, subject labels can be located into a 3D space. Complex information, such as, the relationship between subject labels and weights of respective subject labels can be presented by displaying the 3D space. In this way, the screen size can be reduced and the user experience is improved.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims priority under 35 U.S.C. §119 from ChinesePatent Application No. 200710167211.4 filed Nov. 1, 2007, the entirecontents of which are incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to displaying and/or browsing a data setin a multi-faceted way. In particular, to a method and device for 3Ddisplaying and/or browsing a data set from multiple facets each of whichis a hierarchy of subject labels.

2. Description of the Related Art

Metadata is information about information. In many cases, a set ofhierarchical subject labels is used as metadata for categorizingresources, e.g., Yahoo Directory and ODP (Open Directory Project). Amulti-faceted browsing interface introduces multiple orthogonal sets ofhierarchical subject labels to categorize resources and enables the userto narrow the scope of resources from different points of view viaselecting subject labels in different facets. Multi-faceted browsing hasbeen proven an efficient and interactive way to access resources and hasbeen implemented for browsing a lot of web resources. For example, insome mp3 repository web sites, songs are categorized by artists, genres,region, length, etc. The user can select subject labels under thesefacets to narrow the scope and find songs of his/her interest. Forexample, if the user selects the “Region” facet, the subject labels like“North America”, “Europe”, etc. under the “Region” facet are displayed,and the user can select one certain subject label to narrow thesearching scope from this geography facet.

In most multi-faceted browsing interfaces, subject labels under the sameparent node are displayed as a text list and ranked by the numberresource items under them. This kind of approaches has two majordisadvantages: first, this straight list style display is not capable ofdemonstrating complex information, i.e., relationships between subjectlabels, the relativities between subject labels and user's profile,etc.; second, when there are too many subject labels under a facetcategory, the list will become too long for the screen to display andthis disadvantage will become even worse in small screen devices such asmobile phones.

To illustrate the above disadvantages, the Flamenco Search Interface(see http://flamenco.berkely.edu/demos.html, which is accessible as ofJan. 24, 2011) has implemented a multi-faceted browsing interface on thedata set of Nobel Prize Winners, as shown in FIG. 1, which provides datasearching for Nobel Winners over the past years from many facets(including “Gender”, “Prize”, “Country”, “Year”). In FIG. 1, the subjectlabels under each facet are displayed as a text list. For example, underthe facet “Country”, subject labels “America”, “China”, “Japan”, etc(countries owning prize winners) are displayed as a list; under thefacet “Year”, subject labels “1910-1920”, “1920-1930”, etc. (when theprizes were awarded) are displayed as a list; under the facet “Prize”,subject labels such as prize types “Physics”, “Chemistry”, etc, arelisted. The above-mentioned solution cannot display complex information,such as, which subject label is more important or the relationshipsbetween the subject labels. For example, the relativities betweencountries can be represented by the geographical distances between theircapitals but the list display style is not complex enough to representsuch information. Also, the list is too long to be displayed in a smallscreen. Although a number of solutions have been proposed to improvemulti-faceted browsing interface usage in a screen of small size, theyare mostly 2D based solutions and cannot represent the complexinformation mentioned above.

SUMMARY OF THE INVENTION

The present invention provides a solution for displaying and/or browsinga data set in multi faceted way. In the solution, a plurality of subjectlabels can be allocated in a 3D space. Through a 3D view, complexinformation, such as relationships between the subject labels andweights of subject labels, can be represented by their location in 3Dspace. First, for the sake of clarity, some definitions are introducedas follows and will be discussed subsequently.

Facet: A facet is a set of hierarchical (layered) subject labels, whichis also metadata for describing resources.

Subject Label: A subject label is a node in the hierarchy. Subjectlabels can be used to categorize resources in terms of subjects.

Resource: A resource refers to content to be browsed via a multi-facetedinterface.

Resource Item: A resource item is a unit of the resource.

One embodiment of the present invention provides a 3D multi-facetedbrowsing solution. In the 3D multi-faceted browsing solution a pluralityof subject labels under one facet are allocated into a 3D space anddisplayed to the user. In this way, complex information (such asrelationships between subject labels and weights of subject labels) canbe displayed. Further, this approach helps to reduce the screen sizeoccupied by displaying the information.

In a further aspect, the user's viewpoint can be moved in the displayed3D space.

In a further aspect, the user can click a certain subject label to viewsub-labels/resource items thereof.

In a further aspect, a smooth switch can be made between differentfacets so that user can browse the resources in a highly interactive wayin the 3D space.

Another embodiment of the present invention provides a displaying methodwhich can be applied to a multi-faceted data set containing hierarchical(layered) subject labels. The method includes the following steps:allocating the subject labels in any subset of the multi-faceted dataset into the 3D space based on metadata information; and displaying aview of the 3D space into which the subject labels have been allocated.The metadata information includes at least one of the followinginformation: hierarchy of subject labels of the multi facet dataset,relationships between respective subject labels of a same layer, andweights of respective subject labels.

In a further aspect, the relationship between the subject labels is thedegree of relativity between the subject labels, measured in terms ofthe same characteristic.

In a further aspect, the weight of the subject label is the degree ofimportance of the subject label, measured in terms of the samecharacteristic.

In a further aspect, the step of allocating the subject labels into the3D space further includes determining distances between respectivesubject labels in the 3D space based on the relationship betweenrespective subject labels.

In a further aspect, the step of allocating the subject labels into the3D space further includes determining distances between the subjectlabels and the user's viewpoint in 3D space based on the weights of thesubject labels.

Another embodiment of the present invention provides a displaying deviceapplied to a multi-faceted data set containing hierarchical (e.g.,layered) subject labels. The displaying device includes: a 3D displayallocation arranger for allocating subject labels in any subset of themulti-faceted data set into a 3D space on the basis of metadatainformation of the multi-faceted data set; and a display unit fordisplaying a view of the 3D space into which the subject labels havebeen allocated. The metadata information includes at least one of thefollowing information: hierarchy of subject labels of the multi-faceteddata set, relationships between respective subject labels of a samelayer, and weights of respective subject labels.

Another embodiment of the present invention provides a browsing devicefor a multi-faceted data set containing hierarchical (e.g., layered)subject labels. The browsing device includes: a user-input unit forreceiving user input; a resource repository for storing themulti-faceted data set containing hierarchical subject labels; a searchengine for searching the resource repository via the user-input unit andoutputting a subset of the multi-faceted data set as an output; a 3Ddisplay allocation arranger for receiving the output of the searchengine and allocating subject labels of the subset of the multi-faceteddata set into a 3D space based on metadata information of themulti-faceted data set; and a display unit for displaying a view of the3D space into which the subject labels have been allocated. The metadatainformation includes at least one of the following information:hierarchy of subject labels of the multi-faceted data set, relationshipsbetween respective subject labels of a same layer, and weights ofrespective subject labels.

BRIEF DESCRIPTION OF THE DRAWINGS

An exemplary method and device are illustrated with reference to thedrawings wherein the same reference signs are used to denote the sameelement. In the following description, for the sake of clarity, specificdetails are illustrated to facilitate fully understanding the method anddevice. However, these embodiments could be implemented without thesespecific details. In other embodiments, to simplify the description,common structures and devices are shown as block diagrams. Those skilledin the art can conceive many modifications and other embodiments basedon the teaching as stated in the description and drawings. Therefore,the present invention is not limited to the disclosed specificembodiments. Other alternative embodiments should be included in thescope of the invention and the inventive concept. Although specificterms are used in the text, they are only used for general descriptionrather than for the purpose of any limitation.

FIG. 1 shows a browsing device in the prior art which could be used in amulti-faceted data set.

FIG. 2A shows a displaying device of the present invention used for amulti-faceted data set.

FIG. 2B shows a displaying method of the present invention used for amulti-faceted data set.

FIG. 3A shows a browsing device of the present invention used for amulti-faceted data set.

FIG. 3B shows a browsing method of the present invention used for amulti-faceted data set.

FIG. 4 shows how relationships between subject labels are mapped to a 2Dview according to the invention.

FIG. 5 shows an embodiment of allocating the hierarchical subject labelsinto a 3D space according to the invention.

FIG. 6 shows a main menu of Embodiment 1 of the invention.

FIGS. 7-8 show a 3D view of Embodiment 1 of the invention.

FIG. 9 shows a zoom-in operation to the 3D view of Embodiment 1 of theinvention.

FIGS. 10-11 show resource items of Embodiment 1 of the invention.

FIG. 12 shows a superposed display of the 3D view and a facet menu ofEmbodiment 1 of the invention.

FIG. 13 shows a superposed display of the 3D view and a facet menu ofEmbodiment 1 of the invention.

FIGS. 14-15 show a view after facet switching in Embodiment 1 of theinvention.

FIG. 16 shows subject labels under facet “Region” in the 3D view inEmbodiment 2 of the invention.

FIG. 17 shows subject labels under facet “Region→Europe” in the 3D viewin Embodiment 2 of the invention.

FIG. 18 shows a facet menu view superposed on the subject labels under“Region→Europe” in the 3D view in Embodiment 2 of the invention.

FIG. 19 shows subject labels under both facets “Region→Europe” and“Genres” in the 3D view in Embodiment 2 of the invention.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

Embodiments of the present invention provide a displaying method and adisplaying device for any data having a multi-faceted hierarchicalstructure. The method and device can automatically display a 3D view ofany data set having a multi-faceted structure.

Referring to FIG. 2A, the device includes a 3D display allocationarranger 203 and a display unit 204. The 3D display allocation arranger203 receives metadata information 201; this metadata information 201 isrelated to a multi-faceted hierarchical data set 202 to be displayed andincludes at least one of the following: facet hierarchy of themulti-faceted data set, relationships between subject labels, andweights of subject labels. The 3D display allocation arranger 203further receives any subset of the multi-faceted hierarchical data set202, and allocates the multi-faceted hierarchical data subset 202 into a3D space based on the metadata information 201 (this will be furtherexplained in detail with reference to the embodiments), then theresultant 3D space view is displayed on the display unit 204.

The display unit 204 could be a conventional display with a 2D screen.It could also be, for example, a projector, or the like, which canproject a 3D image so that the 3D space output from the 3D displayallocation arranger 203 can be directly displayed rather than mapped toa 2D screen. Moreover, the display unit 204 can include other well-knownfunctions in the field of image processing, e.g., various processingrelating to 3D visualization.

FIG. 2B shows a flow chart of a 3D visualization method for amulti-faceted data set.

The method begins with step 2011 and proceeds to step 2012 to define themetadata information of the multi-faceted data set, the metadatainformation comprising at least one of the following information:

-   -   facet hierarchies, including subject labels under each facet,        sub labels (if any) under each subject label, and finally        resource items under each subject label. For example, the        hierarchical structure can be a tree-like structure;    -   relationships between subject labels at the same layer, which        can be quantified and calculated in terms of certain predefined        attributes (such as similarity, distance, etc.); and    -   weights of subject labels that can be interpreted as: a degree        of importance, a degree of relativity with user interest, etc.

The above-mentioned several types of metadata are only illustrativerather than restrictive. The 3D display solution proposed by the presentinvention can display additional complex information, such as, theabove-mentioned relationships and weights, when compared with theprior-art 2D display. However, those skilled in the art can define bythemselves any other metadata information repository based on need. Inthe following, it will further explain how to define metadata incombination with embodiments.

Next, in step 2013, any subset of the multi-faceted data set isallocated into the 3D space based on said metadata information. Duringthe process of allocating subject labels into the 3D space, the subjectlabels are allocated in a visually distinguishable way based on thepreviously defined metadata information. For example, distances betweensubject labels reflect the relationships between subject labels, anddifferent distances between the subject labels and a user's viewpointreflect different weights. In the following, it will further explain the3D allocation process in combination with the embodiments.

Moreover, or alternatively, different sizes, brightness, colors, shadowsand other visual effects are allocated to subject labels according todifferent weights, thereby providing a means to visually distinguish thesubject labels. These visual differences more easily reflect the complexinformation, such as, the relationships between the subject labels andweights thereof. Moreover, the above-mentioned different visual effects(i.e., distances, sizes, brightness, colors and shadows etc. of subjectlabels) could correspond to not only one of the metadata information,but also to any combination of the metadata information.

Finally, in step 2014, the 3D space view is displayed to user, and thisprocess ends in step 2015.

Step 2012, which defines the metadata information, is not an essentialpart of the method of the present invention. The metadata informationcan be predefined, stored, and directly accessed and obtained in step2013.

After generating the above 3D visualization view, it is possible for theuser to perform, by various well known 3D visualization techniques,additional operations in the 3D view; including movingbackward/forward/leftward/rightward, zoom-in, zoom-out, etc.

The present invention is also applicable to an ordinary multi-faceteddata set. Specifically, even if the multi-faceted data set doesn'tdefine relationships between the subject labels or weights of subjectlabels, the subject labels in the multi-faceted data set can still beallocated into the 3D space and displayed to the user. The 3D spaceallocation process can be performed using various methods, includingrandomized allocation. Moreover, any visual effects, including size,brightness, color, shadow, etc. can be used to visually distinguish thesubject labels from one another. Compared with the list display in theprior-art, the 3D display of the present invention can provide a betteruser experience, and in particular, it could be used in displayingdevices with a small screen size, such as mobile phones and PDAs.

Additional embodiments of the present invention further provide a 3Dbrowsing method and device for a multi-faceted data set. The followingwill describe additional preferred embodiments of the present inventionwith reference to FIGS. 3A-3B; wherein the displaying method and deviceas shown in FIGS. 2A-2B are included.

FIG. 3A shows a 3D browsing device for a multi-faceted data set. Thedevice has the following signal flows—Input: user operations, which atleast include a query operation by the user, a 3D display operation ofthe query result, etc.; Output: a 3D display of the multi-faceted dataset.

The 3D multi-faceted browsing device includes a user interactioncomponent 3010, a 3D layout management component 3020 and a displaycomponent 3030.

The user interaction component 3010 is an intermediate layer between theuser and the 3D layout management component 3020. It includes a userinput unit 3011 and a processing switch 3012. The user input includesmouse events, keyboard events, and search keywords input by the user,etc. The user operations from the user input unit 3011 are sent to theprocessing switch 3012. The processing switch 3012 classifies the validoperations into two types: a first type, where it is necessary todownload new items from a resource repository 3022 and generate a new 3Ddisplay, for example, user inputs a new keyword search, or user switchesto other facets; a second type, where it only modifies the 3D view ofcurrent displayed items, for example, user performs zoom-in, zoom-out orother moving operations in the 3D space.

The 3D layout management component 3020 includes: a resource repository3022, a multi-faceted searching engine 3021, a metadata informationrepository 3023, a 3D display allocation arranger 3024, and a 3D layoutcoordinator 3025.

The resource repository 3022 could be a database or a file implementedin various ways wherein resource items categorized according to facetsare saved. For instance, a data set including all the Nobel Winners is aresource repository wherein data related to the winners are categorizedaccording to facets such as “Country”, “Year”, “Prize” etc. Each facetmay have one or more layers so that the resource repository 3022 can beimplemented as a hierarchical tree-like structure. It should beappreciated, the term “resource repository” used in this text refers toa physical and/or logical entity which can store data. For example, theresource repository can be one or more of the following: list, table,file, data storage, relationship database, data table, array, stack,etc. The resource repository 3022 can reside in a logical and/orphysical entity, and/or be allocated between two or more logical and/orphysical entities. The term “resource repository” can further beunderstood as including a database management system for controlling theorganization, storage and searching of data in the database.

The multi-faceted search engine 3021 can search the resource repository3022 based on user input using any known searching techniques. Themulti-faceted search engine 3021 can carry outsingle-facet/multi-faceted searching in various ways. The search resultincludes a subset of the multi-faceted data set. The subset itself mayinclude a hierarchy of subject labels and relationships thereof, anymatched resource items, etc. According to a preferred embodiment of thepresent invention, if the multi-faceted data set is a tree-like datastructure, the search result can be a sub-tree.

The metadata information repository 3023 can be defined by user. Themetadata information repository 3023 defines at least one of thefollowing information: hierarchical subject labels under each facet,relationships between subject labels and weights of each subject label.The specific contents of the repository 3023 are predefined by the userbased on demand. The following will explain more details with referenceto embodiments.

The 3D display allocation arranger 3024 receives any search result, andallocates the search result into a 3D space based on the metadatainformation. The following will explain the 3D space allocation processwith reference to embodiments.

The 3D display allocation arranger 3024 outputs any processing resultsto the display unit 3030, thereby the resultant 3D space is mapped to ascreen of a 2D display unit 3030.

If the user input is an operation of the second type instead of a newsearch, for example, adjusting/modifying an existed 3D display, theprocessing switch 3012 sends the user's moving operation in the 3D spaceto the 3D layout coordinator 3025. The 3D layout coordinator 3025 onlymodifies the existing 3D view without loading any new item. The 3D viewis re-displayed on the display screen of the display unit 3030 (thiswill be explained in detail with reference to the embodiments). The usermay instruct to superpose an additional view on the current 3D view, forexample, an operation menu, a history of operations, etc.

The display unit 3030 can be a conventional display with a 2D displayscreen. However, as understood by those skilled in the art, the displayunit 3030 could be a display of any other type. For example, a projectorwhich can project a 3D image so that the 3D space view from the 3Ddisplay allocation arranger 3024 can be directly displayed.

FIG. 3B further shows a 3D browsing method of the present invention fora multi-faceted data set.

After step 3110 starts, user input is received in step 3111.

In step 3112, user input is classified into two types: a first type,where it is necessary to load new items from a resource repository andgenerate a new 3D display, for example, user inputs a new keywordsearch, or user instructs to switch to other facets; a second type,where it only modifies/adjusts the currently existed 3D view, forexample, user performs zoom-in, zoom-out or other moving operations inthe 3D space.

When it is determined that user input is an input of first type, step3113 is performed wherein the resource repository is searched based onuser input. The search result can be a subset of the multi-faceted dataset. The subset can include hierarchies (e.g., layers) of subjectlabels, relationships between subject labels, matched resource items,etc.

In step 3114, the search result is allocated into the 3D space based onmetadata information. As described above, the metadata informationincludes at least one of the following: hierarchical (layered) subjectlabels under each facet of the multi-faceted data set, relationshipsbetween subject labels, and weights of subject labels.

In step 3116, the 3D space view generated in step 3114 is displayed.

On the other hand, when it is determined that user input is of thesecond type in step 3112, step 3115 is performed. For example, when userinput instructs to move (i.e., the user's viewpoint) in the shown 3Dspace, the existing 3D view is adjusted in step 3115 and is displayed tothe user in step 3116. Alternatively, when user input instructs tosuperpose an operation menu or a history of operations on the 3D space,the requested menu or history information is superposed on the existed3D view in step 3115 and displayed to user in step 3116. After step3116, the process ends in 3117.

In the following descriptions, the 3D displaying and/or browsingsolution for the multi-faceted data set proposed in the embodiments ofthe present invention are discussed in detail with reference toEmbodiment 1 and Embodiment 2.

Embodiment 1

Embodiment 1 of the present invention implements the above-mentioned 3Dmulti-faceted browsing device for a data set of the Nobel winners from1901 to 2007 (including 801 winners).

The data set of the Nobel winners is classified into 4 facets:

-   -   Region: geographical area, including hierarchy of continent and        country    -   Gender: gender of winner    -   Award: subject of award, such as physics, chemistry, etc.    -   Date: year of the award

Each facet can have a plurality of layers based on demand. For example,a subject label of a layer immediately under the “Region” facet is acontinent, a subject label of a layer under a continent is a country,and a resource item in a layer under a country is a Nobel winner; Thereis only one layer of subject labels under “Gender”, which includessubject labels “male” and “female”, and under the layer “male” and“female” there are resource items, i.e., Nobel winners.

The hierarchy of a facet can be predefined in various ways. Taking thefacet “Region” as an example, user defines subject labels in the firstlayer under the facet “Region” as “Asia”, “Europe”, “North America”,“Latin America”, “Pacific”, “Africa”, etc. User further defines subjectlabels under the subject label “Asia”, including “China”, “Japan”,“Korea”, . . . , “Vietnam”, etc. Then, resource items are defined underthe subject label “China”, e.g., Chinese Nobel winners “Zhengning Yang”and “Zhengdao Lee”. Other subject labels and resource items can bedefined in a similar way.

Moreover, the above definitions can be described in a general codelanguage, for example, the hierarchical subject labels under the facet“Region” can be represented as:

 − <configFile name = “facet-config” lastModified = “2007-10-19T15 : 52: 03-00 : 00”>  − <facet name=“region” displayname=“Region”>   − <itemname=“asia” displayname=“Asia”>    <item name=“china”displayname=“China” />    <item name=“japan” displayname=“Japan” />  ... </item>   − <item name=“europe” displayname=“Europe”>  <itemname=“germany” displayname=“Germany” />    <item name=“france”displayname=“France” />  ...  </item>   − <item name=“na”displayname=“North America”>    <item name=“usa” displayname=“USA” /> ...  ...  </item>

Taking the facet “Date” as an example, the user can define subjectlabels under the facet “Date”, i.e., years of “1900-1910”, “1910-1920”,“1920-1930”, “2000-2007”, etc. The above-defined code language may bepresented as follows:

− <facet name=“DATE” displayname=“DATE”> <item name=“1900~1910”displayname=“1900~1910”/> <item name=“1910~1920”displayname=”1910~1920”/> ... </facet>

The user can also define information such as relationships betweensubject labels under the same facet and weights of subject labels.

Specifically, each subject label under each facet can be considered as anode, and relationships between subject labels at the same layer aredefined. In Embodiment 1, there are 11 subject labels in the layer underthe subject label “Asia”, which are countries “China”, “Korea”, “Japan”,“Bangladesh”, . . . , “Vietnam”, respectively. Moreover, distancesbetween these countries can be taken as relationships between therespective subject labels.

For example, we may use the following standard code language torepresent the relationships between “China” (subject label 1) and theother 10 countries (subject label 2 to subject label 11). Therelationships are represented by the value of “Relation”. The value of“Relation” can be calculated based on a distance between two countries,for example, the distance between China (subject label 1) and Korea(subject label 2) is quantified as 956, and the distance between China(subject label 1) and Japan (subject label 3) is quantified as 2098.

<!-- edges --> − <edge source=“1” target=“2”> <datakey=“Relation”>956.0</data> </edge> − <edge source=“1” target=“3”> <datakey=“Relation”>2098.0</data> </edge> − <edge source=“1” target=“4”><data key=“Relation”>3023.0</data> </edge> ... − <edge source=“1”target=“11”> <data key=“Relation”>3381.0</data> </edge> ...

In this way, the relationship between any two subject labels can bedefined.

Moreover, the above-defined relationships between countries can be shownas a 2D view. For instance, using the Spring Algorithm (Eades, P. (1984)“A Heuristic for Graph Drawing,” Congressus Numerantium, pp. 149-160)the relationship between any two of the 11 countries under the facet“Asia” is presented as a 2D view based on “distance”, as shown in FIG.4.

Moreover, the weight, “Importance”, of respective subject labels can befurther defined. In this embodiment, “Importance” is determined bycalculating the number of Nobel winners under each subject label. Forexample, there are two winners under the subject label “China”, thus thevalue of “Importance” is 2; there is one winner under the subject label“Korea”, thus the value of “Importance” is 1; there are 12 winners underthe subject label “Japan”, thus the corresponding value of “Importance”is 12. The code language may be represented as follows:

− <!-- nodes --> − <node id=“1”> <data key=“name”>China</data> <datakey=“importance”>2</data> </node> − <node id=“2”> <datakey=“name”>Korea</data> <data key=“importance”>1</data> </node> − <nodeid=“3”> <data key=“name”>Japan</data> <data key=“importance”>12</data></node> ... − <node id=“11”> <data key=“name”>Vietnam</data> <datakey=“importance”>1</data> </node>

The above hierarchies and layers, relationships between subject labelsand weights of respective subject labels can all be predefined by useras metadata and stored in the metadata repository 3023.

After receiving a search keyword input by the user input unit 3011, theprocessing switch 3012 sends it to a multi-faceted search engine 3021.The multi-faceted search engine 3021 searches the resource repository3022 based on the keyword and obtains a search result. In associationwith this keyword, the result includes: hierarchy of subject labels,relationships of subject labels, and any matched resource items, etc. Ifthe multi-faceted data set is implemented as a tree-like structure, thesearch result could be a sub-tree.

One difference between the present invention and the prior art is thatthe above search result is not directly displayed to user as a text listas shown in FIG. 1, instead, it is further input into a 3D displayallocation arranger 3024 which allocates the search result into a 3Dspace based on the predefined metadata repository 3023.

The 3D allocation arranger 3024 can be implemented in various ways so asto allocate the search result data into a 3D space.

The following descriptions illustrate a 3D space allocation processproposed by the invention.

Referring to FIG. 5, from the perspective of the user's viewpoint, thereis a real screen P′, a virtual visual screen P in parallel, and atrapezoid platform 3D space between the two screens. Based on therelationships between subject labels defined in the metadata repository3023, various known algorithms (e.g., the above-mentioned SpringAlgorithm by Eades, P.) may be adopted to generate a 2D view reflectingthe relationship between subject labels. Then the 2D view is mapped to a2D virtual visual screen P so that a subject label is located on the 2Dvirtual visual screen. In this particular case, for example, a subjectlabel is located on the point A in the screen P. Further, based on theweights of respective subject labels, a value of a distance from theuser's viewpoint is assigned to a subject label so that A is furtherlocated in the trapezoid platform space as a point A′. If subject labelshave different weights, their distances from the user's viewpoint willbe different as well. For instance, if the weight is greater, thesubject label will be closer to the user's viewpoint, thereby providinga much more intuitive and comfortable experience for users.

In the above 3D allocation process, a 2D view (X-Y) is first generatedbased on relationship parameters (which could be a 2D matrix M) betweensubject labels, and then a 3D view is obtained by allocating a thirdfacet coordinate (Z) based on weight parameters of the subject labels(which could be a one-facet vector V).

However, as appreciated by those skilled in the art, there are otherways to realize this process. For example, a 3D visual view can bedirectly generated based on the relation parameters (2D matrix M)between subject labels and then the visual effects, such as size, color,light or shadow, of subject labels in the 3D space are set based onweight parameters (one facet vector V) of subject labels. (See Kumar, A.and Fowler, R. (1994) “A spring modeling algorithm to position nodes ofan undirected graph in three facets”, Technical Report, Department ofComputer Science, University of Texas.). Alternatively, 3D spacecoordinates (X, Y, Z) could be calculated directly from relationparameters (2D matrix M) between subject labels and weight parameters(one facet vector V) of subject labels. In short, various ways could beused to map 2D relation parameters and 1D importance parameters (M, V)to (X, Y, Z) in one step or more separate steps. Namely, f(M, V)→(X, Y,Z) can be done by various known algorithms f. Those skilled in the artcan select a 3D allocation solution by considering various factors,e.g., complexity of calculations, costs of hardware/software andexperience of users.

In one simple way, for example, the user might manually set 3Dcoordinates for every subject label based on the predefined relationshipbetween subject labels and weights of subject labels so as to directlymap a subject label into a 3D space.

It should be noted that the present invention is not limited to anyspecific algorithm. Nor does the implementation of the embodiments relyheavily upon any specific algorithm. An aspect of the present inventionis to allocate facets and hierarchical subject labels into a 3D space soas to visually present more complex information to users. By displayingsubject labels, which are allocated into the 3D space based on metadatainformation, the present invention is able to present more complexinformation than a list, as shown in FIG. 1. The complex informationcould be relationships between subject labels, weights of subjectlabels, etc. Illustration is given with reference to the drawings asfollows.

FIG. 6 shows a main interface of the multi-faceted browsing device ofEmbodiment 1. The button “Result” (shown as a circle in the center)changes the main interface to a search result page, similar to a“search” button of a search engine page. The surrounding areas representdifferent facets, e.g. “Region”, “Gender”, “Award”, and “Date”. In thefollowing description this main interface is referred to as a facetmenu.

Once the user clicks the facet “Region”, this operation input is sent tothe processing switch 3012 by the user input unit 3011 shown in FIG. 3A.According to the type of user operation input (need to load new data ornot), the processing switch 3012 transmits this operation input to themulti-faceted search engine 3021 shown in FIG. 3A. The multi-facetedsearch engine 3021 searches the resource repository 3022 based on thekeyword “Region”, and then sends the search results to the 3D displayallocation arranger 3024. The search results include subject labelsunder the facet “Region”, such as “Asia”, “Europe”, “North America”,“Latin America”, “Pacific”, “Africa”, etc. Thereafter, according to theabove-mentioned 3D allocation process, the 3D display allocationarranger 3024, allocates search results into a 3D space according torelationships between subject labels and weights of subject labels asdefined in the metadata repository 3023. The 3D display allocationarranger 3024 presents the resultant 3D space to the display unit 3030.The display unit 3030 displays this 3D space, as illustrated in FIG. 7.

FIG. 7 displays the subject labels of the layer under the facet “Region”in the 3D space, i.e., “Asia”, “Europe”, “North America”, “LatinAmerica”, “Pacific”, “Africa”, etc. The numbers in the parenthesis afterthe subject labels represent the number of winners in each continent.

If the user further clicks on “Asia (31)”, this operation input is alsosent to the processing switch 3012 by the user input unit 3011. Theprocessing switch 3012 sends this operation input to the multi-facetedsearch engine 3021 based on the type of this user operation input,wherein new data need to be loaded. The search engine 3021 searches theresource repository 3022 based on the selection of subject label “Asia”under the “Region” facet. The search results are subject labels underthe layer “Asia”, i.e., “China”, “Korea”, “Japan”, “Bangladesh” . . .“Vietnam”. Thereafter, the search results are sent to the 3D displayallocation arranger 3024. The 3D display allocation arranger 3024allocates the search results into a 3D space according to therelationships between subject labels and the weights of subject labelsas defined in metadata repository 3023, and provides the 3D space to thedisplay unit 3030. The display unit 3030 shows this 3D space. As shownin FIG. 8, it displays countries under “Asia” as the subject labels inthe 3D space.

In the interface illustrated in FIGS. 7-8, the following complexinformation can be displayed:

-   -   relationships between subject labels: the relationships are        presented in terms of the distances between the countries (or        continents). For example, in FIG. 8, “Japan”, “China” and        “Korea” are displayed adjacently because they are geographically        adjacent to each other.    -   weights of subject labels: This property can be defined by        users. In the present embodiment, the weight is determined in        terms of the number of winners. If the number of winners in one        subject label is more than that in another subject label, it        will be allocated closer to the user's viewpoint.

As a result, in the 2D real screen, this subject label is displayedbigger.

It should be noted in particular that the relationships between subjectlabels and the weights of subject labels can be flexibly defined. Forexample, the relationships between subject labels could be relativitybetween subject labels measured in terms of the same characteristic. Theweights of subject labels could be the degree of importance of thesubject labels measured in terms of the same characteristic. The abovementioned relationships between subject labels and weights of subjectlabels could be predefined in the metadata repository based on demand.

If many subject labels are allocated in the 3D space at the same time,some labels may not be clearly displayed, for example, some labels aretoo far from the user's viewpoint or are too small. In a further aspectof the present invention, users can use a “zoom in” operation to viewthe space from a closer viewpoint. The “zoom in” operation by user issent to the processing switch 3012 through the user input unit 3011 asshown in FIG. 3A. Based on the type of this operation, the processingswitch 3012 sends the operation instruction to the 3D layout coordinator3025, wherein this operation only modifies the shown 3D space viewwithout loading any new content. The 3D layout coordinator 3025 adjuststhe 3D space display according to the user's operation. For instance,the 3D view after the adjustment of “zoom in” operation is shown in FIG.9.

As known by those skilled in the art, various 3D visualized techniquescould be applied to adjust the existed 3D space view so as to adapt tothe user's viewpoint movement in this virtual 3D space. For example, anew trapezoid platform 3D space can be displayed based on a new user'sviewpoint produced by user input. Alternatively, by keeping the user'sviewpoint unchanged and adjusting the position and angle of thetrapezoid platform 3D space based on user input, an adjusted 3D spacecould be displayed.

After a “zoom in” operation, the user clicks on the subject label “China(2)” in FIG. 9 so as to instruct the expansion of the subject label“China (2)”. This user input can be sent to the processing switch 3012through the user input unit 3011 shown in FIG. 3A. Based on the type ofthis operation input, the processing switch 3012 sends the useroperation input to the multi-faceted search engine 3021 shown in FIG.3A. The multi-faceted search engine 3021 searches the resourcerepository 3022 based on the keyword “China”, thus the search result isthe resource items under the subject label “China”, i.e., the twowinners in China. Then the search result is sent to the 3D displayallocation arranger 3024 which directly allocates the resource items onthe screen. In this embodiment, the resource items themselves do notdefine metadata information. On the other hand, if the resource itemshave metadata information, the resource items per se are equivalent tothe subject labels. After that, resource items are output to the displayunit 3030. Therefore, the display unit 3030 displays the resource items.The view after the expansion operation is illustrated in FIG. 10,wherein 2 winners under the subject label “China” are displayed.

The user can further click on any resource item in FIG. 10 to seedetails of this resource item, e.g., introductions of winners shown inFIG. 11.

Moreover, the multi-faceted browsing device of one embodiment of thepresent invention could be further implemented in combination with mp3and other multimedia files to trigger media players to play the selectedmp3 or multimedia files.

In another embodiment, the user may click on a preset button if he/shewants to view the main facet menu. This user operation input can be sentto the processing switch 3012 through the user input unit 3011 shown inFIG. 3A. Based on the type of this operation input, the processingswitch 3012 can send this operation input to the 3D layout coordinator3025. Please note, this operation only superimposes a menu on thedisplay without loading any new content. The 3D layout coordinator 3025superimposes the main facet menu on the current 3D view, and thenoutputs it to the display unit 3030. The display unit 3030 displays thefacet menu as shown in FIG. 12, which is superimposed on the view ofFIG. 11. In one aspect of the present invention, each operation of theuser is recorded in a selection history so that the facet menu canfurther show the selection history of previous operations, e.g., theoperations of “Region”→“Asia”→“China”.

In one aspect of the present invention, the menu interface of FIG. 12further allows user to move backward and change the selection history byoperating the menu. For example, if the user clicks on the facet menu“Asia (31)”, as shown in FIG. 12, to erase the selection of the subjectlabel “China”, this user input operation is sent to the processingswitch 3012 through the user input unit 3011. The processing switch 3012can send this operation to the 3D layout coordinator 3025 whichretrieves the existing 3D view (as shown in FIG. 8) and superimposes thedisplay operation menu so that the interface as shown in FIG. 13 occurs.

Moreover, if user clicks the “Gender” facet on FIG. 13 to instructselecting another facet, this user operation input will be sent to theprocessing switch 3012 through the user input unit 3011 as shown in FIG.3A. Based on the type of this operation, the processing switch 3012sends this operation to the multi-faceted searching engine 3021 whichfurther searches the existing search results based on “Gender”, andoutputs the search results to the 3D display arranger 3024. The 3Ddisplay arranger 3024 allocates the new search results to a 3D space asillustrated in FIG. 14. FIG. 14 shows to the user a search based on thecombination of the two facets of “Region→Asia” and “Gender”. The numbersin the parenthesis after the subject label represent the number of“Male” winners and the number of “Female” winners in “Asia”respectively.

Further, if the subject label “Female”, under the facet “Gender”, inFIG. 14 is selected, the subject label is expanded. The expandedresource items are displayed in FIG. 15, including 3 female Nobelwinners in Asia. Moreover, the main facet menu (which can be triggeredby a preset button) is superimposed in FIG. 15. The main facet menucomprises the selection history of “Region→Asia” and “Gender→Female”.Thus FIG. 15 shows the resource searched by user and the search history,“Region→Asia” and “Gender→Female”, at the same time.

It should be noted that the above mentioned Embodiment 1 is onlyexemplary. In particular, the metadata defined in the metadatarepository including facet hierarchy, relationships between subjectlabels and weights of subject labels are all predefined by the userbased on the data set of Nobel Prize winners.

Actually, in response to any multi-faceted hierarchical data set, theuser can define a corresponding metadata information repository so as todisplay a multi-faceted hierarchical data set in a 3D space view.Embodiment 2 of the present invention is further explained as follows.

Embodiment 2

The 3D multi-faceted browsing device of the present invention isimplemented on a song repository in Embodiment 2. The portion similarwith Embodiment 1 is omitted. Embodiment 2 can define the following fourfacets:

-   -   Region    -   Genre    -   Singer    -   Date

Based on demand of users, a metadata repository can predefine thefollowing contents:

-   -   (1) The hierarchical subject labels under each facet    -   (2) The relationship between subject labels    -   (3) Weights of respective subject labels

For example, in Embodiment 2, the subject label under the “Region” facetis “Continent”, and the relationships between such subject labels isrepresented by the distance between the “Continents”. For example, thedistances between subject labels such as “North America”, “SouthAmerica”, and “Europe” correspond to their geographical vicinity. Each“Continent” further includes other subject labels corresponding torespective countries.

As shown in FIG. 19, the subject labels under the facet “Genres” aremusic of various styles, such as “Jazz”, “Country Music”, “Electronic”,“Rap”, etc. As shown in FIG. 19, the similarity between genres isrepresented as the distance between subject labels, i.e., relationshipsbetween subject labels.

In Embodiment 2, the “weight” of each subject label is calculated basedon the degree of the user's interest (e.g., the frequency of playing).The “weight” can alternatively be calculated based on the number ofsongs under each subject label or based on the sequence of updating.

The main menu of Embodiment 2 is substantially the same as that ofEmbodiment 1. The following descriptions illustrate how to browse thesong repository based on the multi-faceted browsing device of thepresent invention.

First, the user selects the “Region” facet. The user input operation issent to the processing switch 3012 through the user input unit 3011 inFIG. 3A. The processing switch 3012 sends the user operation input tothe multi-faceted searching engine 3021 in FIG. 3A. The multi-facetedsearching engine 3021 further searches the resource repository 3022based on the selection of subject label “Region”. The search results aresubject labels of the layer under the subject label of “region”, i.e.,“North America”, “South America” and “Europe”. Then, the multi-facetedsearching engine 3021 transmits the search result to the 3D displayallocation arranger 3024. According to the metadata defined in themetadata information repository 3023, the 3D display location arranger3024 allocates the search results for “Region” into the 3D space andprovides the 3D space to the display unit 3030. The display unit 3030displays this 3D space, as illustrated in FIG. 16. In FIG. 16, aplurality of subject labels, i.e., “North America”, “South America” and“Europe” (the sub-subject labels under the facet “Region”) aredisplayed. The distance between subject labels “North America”, “SouthAmerica” and “Europe” corresponds to their geographical vicinity.Moreover, the subject labels “North America”, “South America” and“Europe” are assigned different distances to the user's viewpointaccording to their weights.

In the 3D space shown in FIG. 16, in the same manner as Embodiment 1,the user can move forward/backward/leftward/rightward using a mouse orkeyboard to view the 3D space in a global or local way.

In the same manner as Embodiment 1, the user can click on a subjectlabel to expand the sub-node thereof. Suppose the user clicks on thesubject label “Europe” in FIG. 16, then a new 3D view is generated basedon the search results for “Europe”. Thus, an expansion view of “Europe”is displayed, as shown in FIG. 17, which displays various countries in“Europe”, such as “France”, “Greece”, “Spain”, etc.

In the same manner as Embodiment 1, the user can trigger a facetoperation menu by pressing a preset button. In the view as illustratedby FIG. 18, the facet operation menu is displayed in an overlappingmanner on the view of FIG. 17, wherein the previously selected operationhistory “Region”→“Europe” is also displayed.

The user may switch to other facets by clicking on the operation menu.For example, user clicks “Genres” in the menu of FIG. 18, and a searchis further performed for “Genres” in the existing search results (i.e.,the search results for “Region”→“Europe”). The newly obtained searchresults are allocated into the 3D space. As shown in FIG. 19, music ofvarious genres, such as “Jazz”, “Country Music”, “Electronic”, “Rap”,etc, are allocated into the 3D space.

It should be noted that the present invention is not limited by theparticular visualization of the facet menu. Instead, the operation menucan be displayed in various known ways, e.g., to be displayed as table,list and etc.

Although Embodiments 1 and 2 are data sets of Nobel winners and songsrespectively, they are only exemplary. Based the principle as disclosedabove, those skilled in the art are able to conceive that the presentinvention can be applied in processing any data set having amulti-faceted hierarchical structure. This includes displaying,browsing, classifying, and traversing a multi-faceted data set, andvisually displaying complex information in the 3D space, e.g.,relationships between subject labels under respective facets and weightsof subject labels.

It should be noted that some or all steps of the methods of the presentinvention relate to electronic and/or software application. Theapplication can be a dynamic and flexible process, and thus the methodsteps can be implemented in other sequences that are different fromabove-mentioned. Those skilled in the art are able to conceive that thecomponents of the device can be implemented using various programmingtools, e.g., machine language, program language, object oriented and/orartificial intelligence techniques, etc. Any suitable digital signalprocessing circuits, software control processors, special IC orequivalent circuits can also be used to perform the processing mentionedin this description. Components implemented as software are not limitedto any specific program language. Instead, the description providesinformation to those skilled in the art that can be used to producecircuits or software to perform the invention. It should be noted thatsome or all parts of the present device and method can be implemented aslogics mentioned above.

Furthermore, the device and method mentioned in this description can bestored in a computer readable medium. The medium may include but notlimited to, ASIC, CD, DVD, RAM, ROM, PROM, disc, signal carrier, memorystick, etc.

Although the present invention is described by referring to thepreferred embodiments, it should be appreciated that the presentinvention is not limited to the specific embodiments as disclosed. Thescope of the following claims conforms to the broadest explanation, soas to include all the modifications, equivalent structures andfunctions.

1. A method for displaying a multi-faceted data set containing hierarchical subject labels, comprising the steps of: allocating, using a 3D display arranger device, the subject labels in any subset of the multi-faceted data set into a 3D space based on metadata information of the multi-faceted data set; displaying, using a display device, a view of the 3D space into which the subject labels have been allocated; wherein the metadata information includes weights of respective subject labels; wherein relationships between the subject labels are the degrees of relativity between the subject labels measured in terms of a same characteristic; wherein the step of allocating the subject labels into the 3D space further comprises the step of determining distances between the subject labels and a user's viewpoint based on the weights of the subject labels; wherein at least one of the steps is carried out using a processor device.
 2. The displaying method of claim 1, further comprising the steps of: searching the multi-faceted data set based on a user input to produce search result data; and taking the search result data as the subset.
 3. The displaying method of claim 1, wherein the step of displaying the view of the 3D space further comprises the step of displaying the subject labels together with the related metadata information.
 4. The displaying method of claim 1, wherein the step of displaying the view of the 3D space further comprises the step of adjusting a view of the 3D space in response to a moving operation of a user input.
 5. The displaying method of claim 1, wherein the metadata information further includes a hierarchy of subject labels of the multi-faceted data set and relationships between respective subject labels of a same layer.
 6. An apparatus for displaying a multi-faceted data set containing hierarchical subject labels, comprising: a 3D display allocation arranger device for allocating the subject labels in any subset of the multi-faceted data set into a 3D space on the basis of metadata information of the multi-faceted data set; a display device for displaying a view of the 3D space into which the subject labels have been allocated; a processor device for storing the metadata information; wherein the metadata information includes weights of respective subject labels; wherein relationships between the subject labels are the degrees of relativity between the subject labels measured in terms of a same characteristic; wherein the 3D display allocation arranger determines distances between the subject labels and a user's viewpoint based on the weights of the subject labels.
 7. The displaying apparatus of claim 6, wherein the apparatus further comprises: a user-input for receiving user input; a resource repository for storing the multi-faceted data set containing hierarchical subject labels; and a search engine for searching the resource repository via the user-input unit and outputting a subset of the multi-faceted data set as an output.
 8. The browsing apparatus of claim 6, wherein the metadata information further includes a hierarchy of subject labels of the multi-faceted data set and relationships between respective subject labels of a same layer.
 9. A method for displaying a multi-faceted data set containing hierarchical subject labels, comprising the steps of: allocating, using a 3D display arranger device, the subject labels in any subset of the multi-faceted data set into a 3D space based on metadata information of the multi-faceted data set; displaying, using a display device, a view of the 3D space into which the subject labels have been allocated; wherein the metadata information includes weights of respective subject labels; wherein the weights of the subject labels are the degrees of importance of the subject labels measured in terms of a same characteristic; wherein the step of allocating the subject labels into the 3D space further comprises the step of allocating visual effects to the subject labels in the 3D space on the basis of the metadata information; wherein at least one of the steps is carried out using a processor device.
 10. The displaying method of claim 9, further comprising the steps of: searching the multi-faceted data set based on a user input to produce search result data; and taking the search result data as the subset.
 11. The displaying method of claim 9, wherein the step of displaying the view of the 3D space further comprises the step of displaying the subject labels together with the related metadata information.
 12. The displaying method of claim 9, wherein the step of displaying the view of the 3D space further comprises the step of adjusting a view of the 3D space in response to a moving operation of a user input.
 13. The displaying method of claim 9, wherein the metadata information further includes a hierarchy of subject labels of the multi-faceted data set and relationships between respective subject labels of a same layer.
 14. An apparatus for displaying a multi-faceted data set containing hierarchical subject labels, comprising: a 3D display allocation arranger device for allocating the subject labels in any subset of the multi-faceted data set into a 3D space on the basis of metadata information of the multi-faceted data set; a display device for displaying a view of the 3D space into which the subject labels have been allocated; a processor device for storing the metadata information; wherein the metadata information includes weights of respective subject labels; wherein the weights of the subject labels are the degrees of importance of the subject labels measured in terms of a same characteristic; wherein the 3D display allocation arranger further determines a visual effect of the subject labels in the 3D space on the basis of the metadata information.
 15. The browsing apparatus of claim 14, wherein the apparatus further comprises: a user-input for receiving user input; a resource repository for storing the multi-faceted data set containing hierarchical subject labels; and a search engine for searching the resource repository via the user-input unit and outputting a subset of the multi-faceted data set as an output.
 16. The browsing apparatus of claim 14, wherein the metadata information further includes a hierarchy of subject labels of the multi-faceted data set and relationships between respective subject labels of a same layer. 